Structure for electrically connecting a first body of semiconductor material overlaid by a second body of semiconductor material, composite structure using the electric connection structure, and manufacturing process thereof

ABSTRACT

An electric connection structure connecting a first silicon body to conductive regions provided on the surface of a second silicon body arranged on the first body. The electric connection structure includes at least one plug region of silicon, which extends through the second body; at least one insulation region laterally surrounding the plug region; and at least one conductive electromechanical connection region arranged between the first body and the second body, and in electrical contact with the plug region and with conductive regions of the first body. To form the plug region, trenches are dug in a first wafer and are filled, at least partially, with insulating material. The plug region is fixed to a metal region provided on a second wafer, by performing a low-temperature heat treatment which causes a chemical reaction between the metal and the silicon. The first wafer is thinned until the trenches and electrical connections are formed on the free face of the first wafer.

TECHNICAL FIELD

[0001] The present invention regards a structure for electricallyconnecting a first body of semiconductor material overlaid by a secondbody of semiconductor material, a composite structure using the electricconnection structure and a manufacturing process.

BACKGROUND OF THE INVENTION

[0002] In particular, the invention can be used for electricallyconnecting a first silicon wafer incorporating electronic components toa second silicon wafer incorporating a micromechanical structure and/orto the outside. The invention can likewise be used for electricallyconnecting the first wafer to a third body carried by the second wafer,as well as for connecting the first wafer to the outside when the firstwafer is covered by a protection structure, and thus is not directlyaccessible. An example of a particular application is represented by amicro-electromechanical system including a first wafer incorporating acircuit for controlling the parameters defining the state of amicro-electromechanical structure (for example, the position of amicroactuator); a second wafer incorporating the micro-electromechanicalstructure; and a third wafer forming a cap for protecting themicro-electromechanical structure.

[0003] Various techniques are known for mechanically connecting twosemiconductor material bodies (see, for example, Martin A. Schmidt,“Wafer-to-Wafer Bonding for Microstructure Formation”, Proceedings ofthe IEEE, Vol. 86, No. 8, August 1998). However, such techniques do notenable two or three wafers to be electrically connected, in addition tobe mechanically connected, or covered components of one of the wafers tobe electrically accessed.

SUMMARY OF THE INVENTION

[0004] An embodiment of the present invention provides a connectionstructure that enables semiconductor material bodies made on differentsubstrates to be overlaid and to be connected mechanically andelectrically together and to the outside.

[0005] According to embodiments of the present invention, an electricconnection structure, a composite structure, and a process formanufacturing a composite structure are provided. The electricconnection structure connects a first silicon body to conductive regionsprovided on the surface of a second silicon body arranged on the firstbody. The electric connection structure includes at least one plugregion of silicon, which extends through the second body; at least oneinsulation region laterally surrounding the plug region; and at leastone conductive electromechanical connection region arranged between thefirst body and the second body, and in electrical contact with the plugregion and with conductive regions of the first body. To form the plugregion, trenches are dug in a first wafer and are filled, at leastpartially, with insulating material. The plug region is fixed to a metalregion provided on a second wafer, by performing a low-temperature heattreatment which causes a chemical reaction between the metal and thesilicon. The first wafer is thinned until the trenches and electricalconnections are formed on the free face of the first wafer.

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] For a better understanding of the present invention, preferredembodiments thereof are now described, merely to provide non-limitingexamples, with reference to the attached drawings, wherein:

[0007]FIGS. 1 and 2 are cross-sections through a semiconductor materialwafer, in two successive manufacture steps, according to a firstembodiment of the invention;

[0008]FIG. 3 shows a cross-section through the wafer of FIG. 2, afterbonding to a second semiconductor material wafer;

[0009] FIGS. 4-6 show cross-sections of the multiwafer structure of FIG.3, in successive manufacture steps;

[0010]FIG. 7 is a perspective view of the left-hand half of themultiwafer structure of FIG. 6;

[0011]FIG. 8 shows a cross-section of the multiwafer structure of FIG.6, in a final manufacture step;

[0012] FIGS. 9-11 show cross-sections of a micro-electromechanicalsystem according to a second embodiment of the invention;

[0013]FIG. 12 shows a cross-section of a composite structure formedstarting from three semiconductor material substrates, according to athird embodiment of the invention;

[0014]FIGS. 13 and 14 show cross-sections of a semiconductor materialwafer, in two successive manufacture steps according to a fourthembodiment of the invention;

[0015]FIG. 15 shows a cross-section of the wafer of FIG. 14 afterbonding to a second semiconductor material wafer;

[0016]FIG. 16 shows a cross-section of a composite structure obtainedfrom the double wafer of FIG. 15, in a subsequent manufacture step;

[0017]FIG. 17 shows a cross-section of a composite wafer, according to afifth embodiment of the invention; and

[0018]FIGS. 18 and 19 show cross-sections of a composite wafer,according to a sixth embodiment of the invention, in two successivemanufacture steps.

DETAILED DESCRIPTION OF THE INVENTION

[0019] FIGS. 1-8 show a first embodiment of a process for manufacturinga micro-electromechanical system, including a control and sensingcircuitry and a micro-electromechanical sensor, for example anacceleration sensor.

[0020] Initially, as illustrated in FIG. 1, a first wafer 1 ofsemiconductor material, typically P++ or N++ doped monocrystallinesilicon, illustrated as sectioned along two parallel half-planes so asto show different areas in the left-hand half and in the right-handhalf, is masked and etched to form first deep trenches 2 a. For example,the first wafer 1 may have a conductivity of between 5 and 15 mΩ/cm,preferably 10 mΩ/cm. As shown in FIG. 2, the first trenches 2 a have aclosed shape and enclose monocrystalline silicon plug regions 3 intendedto form through connections, as explained more clearly hereinafter.

[0021] Subsequently, the first trenches 2 a are filled, eithercompletely or partially, with insulating material 6, for example silicondioxide. To this end, a silicon dioxide layer is deposited or grown, andis subsequently removed from a first surface 7 of the first wafer 1, toobtain the structure shown in FIG. 2.

[0022] Next, as illustrated in FIG. 3, the first wafer 1 is bonded to asecond wafer 10 formed of a monocrystalline silicon substrate 11 and aninsulation and/or passivation layer 12. In particular, the substrate 11houses conductive and/or insulating regions forming electroniccomponents for biasing the acceleration sensor 8 and for detecting andprocessing electrical signals generated by the acceleration sensor 8. Asan example, FIG. 3 shows conductive regions 15-16 of the N/P-typebelonging to an electronic circuit 40, which is shown onlyschematically. In addition, the insulation and/or passivation layer 12houses metal regions 13, 18, which terminate, at one or both of theirends, with pad regions 19 facing the surface 22 of the second wafer 10.

[0023] Connection regions 23 are provided on the surface 22 of thesecond wafer 10, on top of the pad regions 19, and are of a metal thatis able to react at a low temperature with the silicon of the firstwafer 1 to form a gold/silicon eutectic or a metallic silicide.Typically, the connection regions 23 are made of gold, in the case wherethe aim is to obtain a eutectic, or of a metal chosen from among thegroup comprising palladium, titanium, and nickel, in the case where theaim is to obtain a silicide. Bonding regions 24 are also provided on thesurface 22 and are preferably formed at the same time as the connectionregions 23.

[0024] For bonding the first wafer 1 to the second wafer 10, the firstwafer 1 is turned upside down so that the first surface 7 of the firstwafer 1 faces the second wafer 10. The plug regions 3 of the first wafer1 are brought into contact with the connection regions 23 of the secondwafer 10, and subsequently a heat treatment at low temperature, forexample 350-450° C., is carried out for a period of 30-45 minutes, sothat the metal of the connection regions 23 of the second wafer 10 reactwith the silicon of the plug regions 3 and form a metallic silicidewhich bonds the first and the second wafers 1, 10. Thereby, a doublewafer 25 is obtained, as shown in FIG. 3.

[0025] Subsequently, as illustrated in FIG. 4, the first wafer 1 isthinned from the back mechanically, for example by grinding, preferablyso as to obtain a thickness of 30-40 μm. The first wafer 1 then has asecond surface 26 opposite to the first surface 7.

[0026] Next, as illustrated in FIG. 5, a metal layer, for example, analuminum layer, is deposited and defined, so as to form metal regions 27extending above the plug regions 3 and in direct electrical contact withthe latter.

[0027] Subsequently, the first wafer 1 is masked and etched so as toform second trenches 2 b defining an acceleration sensor 8. Inparticular, as may be seen in FIGS. 6 and 7, the second trenches 2 bseparate a mobile region, forming a rotor 4, and a fixed region, forminga stator 5, from the rest of the wafer 1 and from one another. The rotor4 is connected, through elastic-connection regions, also referred to assprings 31, to fixed biasing regions 32, which are set in areascorresponding to respective connection regions 23, connected, throughthe metallic regions 13, to the plug regions 3.

[0028] Next, as illustrated in FIG. 8, a cap element 34 is fixed to thewafer 1 through adhesive regions 36, in a per se known manner, and thenthe double wafer 25 is cut into individual dice. Finally, the metalregion 27 is contacted applying the usual wire-bonding technique.

[0029] Thereby, the connection regions 23 ensure mechanical connectionbetween the monocrystalline silicon wafers 1 and 10 and electricalconnection between the surface 22 of the second wafer 10 and the plugregions 3. In turn, the plug regions 3 allow the second wafer 10 to becontacted from above. In particular, some plug regions 3 enable thesecond wafer 10, not directly accessible from the front, to be connectedto the outside, without requiring costly processes to be carried outfrom the back. In addition, as is shown in the left-hand half of FIG. 8,this solution also enables connection of regions formed in the firstwafer 1 to the outside. Here the rotor 4 is connected to the outsidethrough a first connection region 23 (beneath the biasing region 32), ametal region 13, a second connection region 23 (beneath the plug region3), and the plug region 3. The plug regions 3 are insulated byinsulation regions formed by the insulating material 6 and possibly bythe air present in the first deep trenches 2 a, and are thuselectrically insulated from the rest of the first wafer 1, except,obviously, for the regions connected to them via electric connectionlines 30, shown in FIG. 10.

[0030] With the solution of FIGS. 1-8 a pressure sensor, instead of anacceleration sensor, may be formed.

[0031] FIGS. 9-11 show a second embodiment of the invention regarding aunit for micrometric regulation of the read/write head of a hard-diskdriver. In detail, initially the same steps are carried out as describedpreviously with reference to FIGS. 1-4. After thinning the first wafer1, an oxide layer 35 is deposited and removed selectively at the plugregions 3 to form openings 28. The second trenches 2 b are then formedthrough the oxide layer 35 and through the wafer 1.

[0032] Subsequently, as illustrated in FIG. 10, an insulating layer 38is deposited, for example a stick foil which does not enter the secondtrenches 2 b. The insulating layer is removed from above the openings28, and metal connection regions are formed by depositing and defining ametal layer. In particular, in the illustrated example the metal layerfills the openings 28, where it forms contacts 29. In addition, anelectric connection line 30 is formed and extends from the contact 29arranged above the plug region 3 furthest to the right, up to above therotor 4.

[0033] Subsequently, the composite wafer 25 is cut into dice, theinsulating layer 38 is removed in oxygen plasma, and a ceramic body,referred to as slider 41, is bonded to the rotor 4 in a per se knownmanner (FIG. 11). The slider 41 carries a transducer 42 for datareading/writing on a hard disk (not shown). The transducer 42 iselectrically contacted through connection regions 43, one of which maybe seen in FIG. 11, which are formed directly on one side of the slider41. Each connection region 43 extends from the transducer 42 as far as apad 44 in electrical contact with an electric connection line 30.

[0034] Thereby, the plug region 3 furthest to the right enableselectrical connection between the transducer 42 on the slider 41 and theelectrical circuit 40, which can thus transmit to the transducer 42 thedata to be written, or process the signal picked up by the transducer42. In addition, in a known manner, the electrical circuit 40 controlsmovement of the rotor 4, and consequently of the slider 41. Finally, aconnection via an intermediate plug region (not shown) enablesconnection of the electrical circuit 40 to the outside, in a way similarto that illustrated in the right-hand part of FIG. 8.

[0035] Consequently, also in this case the plug regions 3 enableconnection of non-accessible regions of the second wafer 10 to elementsarranged above them (here, the transducer 42), as well as to theoutside.

[0036]FIG. 12 shows a third embodiment regarding the manufacture ofcircuits or structures to be kept in vacuum conditions. In theillustrated example, the wafer 1, after forming the plug regions 3 bydigging the first trenches 2 a and filling them with insulating material6, has been bonded to a second wafer 10, wherein a filter 48 has beenpreviously made, for example of the band-pass type for high frequencies.The first wafer 1 is bonded to the second wafer 10, not only through theconnection regions 23, but also through a sealing region 49 whichextends between the first wafer 1 and the second wafer 10, andcompletely surrounds the area in which the filter 48 is formed, as wellas the plug regions 3. The sealing region 49 is, for example, made usinga low-melting temperature glass and has a closed shape. If bonding ofthe first wafer 1 and second wafer 10 is carried out in a low-pressureenvironment, the filter 48 remains vacuum encapsulated.

[0037] Next, the first wafer 1 is thinned as described above, and thedouble wafer 1, 10 is cut into dice 50. The dice 50 are then bonded to athird wafer 51 which houses a circuit 52 and which has previously beenprovided with connection regions 23 a similar to the connection regions23. The thinned side of the first wafer 1 faces the third wafer 51, andthe plug regions 3 must be aligned to the connection regions 23 a.

[0038] In this case, the first wafer 1, in addition to protecting andisolating the filter 48 from the outside environment and maintaining itin vacuum conditions, enables its electrical connection with the circuit52 incorporated in the third wafer 51. In addition, it is possible tocarry out electrical testing of the circuit 52 connected to the filter48 at the wafer level (EWS—Electric Wafer Sort test).

[0039] FIGS. 13-16 show a fourth embodiment of the invention. Accordingto FIG. 13, initially the first wafer 1 comprises a substrate 53accommodating first trenches 72 a, and the first trenches 72 a arefilled with insulating material 76 to insulate first plug portions 73,in a way similar to that described with reference to FIG. 1 for the plugregions 3. Then a sacrificial layer 54, for example of silicon dioxide,is deposited or grown, then is masked and etched so as to form openings55 on top of the first plug portions 73 and in areas where anchorageswith the structure on top are to be made, as described hereinafter.

[0040] Subsequently (FIG. 14), a polycrystalline silicon seed layer isdeposited on top of the sacrificial layer 54 and in the openings 55, andthen a polycrystalline silicon epitaxial layer 56 is grown. In this way,the epitaxial layer 56 is in direct contact with the substrate 53 at theopenings 55. Next, inside the epitaxial layer 56 third and fourthtrenches 60 a, 60 b are dug, which reach as far as the sacrificial layer54. In particular, the third trenches 60 a delimit second plug portions62 aligned vertically with the first plug portions 73 in the substrate53, and the third trenches 60 a define a desired micromechanicalstructure (in the example illustrated, a microactuator 57 of therotating type, including a rotor 58 and a stator 59, with the rotor 58supported by springs, which are not illustrated).

[0041] Subsequently, in a known way, a part of the sacrificial layer 54is removed through the fourth trenches 60 b. In particular, thesacrificial layer 54 is removed beneath the rotor 58 to form an air gap63, and it substantially remains underneath the stator 59. Thesacrificial layer 54 is removed only to a very small extent through thethird trenches 60 a, given the different geometry (the micromechanicalstructure is formed by thin regions and/or perforated regions, allowingthe sacrificial layer 54 to be substantially removed; this, instead, isnot done through the third trenches 60 a).

[0042] In a way not shown, it is then possible to fill the thirdtrenches, at least partially, with insulating material, in a way similarto that described for the first trenches 2 a of FIG. 1.

[0043] Subsequently, as illustrated in FIG. 15, the first wafer 1 isturned upside down and bonded to the second wafer 10, inside whichcomponents of the circuit 40 have already been formed, and on top ofwhich the connection regions 23 have already been made. Also in thiscase, a low-temperature heat treatment is carried out to enable achemical reaction between the silicon of the epitaxial layer 56, at thesecond plug portions 62, and the metal of the connection regions 23.Next, the substrate 53 of the first wafer 1 is thinned until theinsulating material 76, or at least the bottom of the first trenches 72a, is reached, an oxide layer 35 is deposited, the openings 28 areformed in the oxide layer 35, and then second trenches 72 b are madewhich separate fixed parts from mobile parts in the substrate 53.

[0044] Next, as has been described with reference to FIG. 10, aninsulating layer, for example stick foil, is deposited and selectivelyremoved, and the electrical contacts 29 and electric connection lines 30are formed. In FIG. 16, an electric connection line 30 connects theportion of the substrate 53 to which the rotor 58 is anchored, forexample at cap region 67, to the first plug region 73 that is furthestto the left, thus enabling electrical connection of the rotor 58 to thecircuit 40 through the cap region 67, the first plug portion 73 on theleft, and the second plug portion 62 on the left. Shown in theright-hand half of FIG. 16 is instead the electrical connection betweenthe circuit 40 and the outside, through the second plug portion 62, thefirst plug region 73, and the connection region 23 on the right.

[0045] Subsequently, the insulating layer is removed, and a body to bemoved, for example a slider similar to the slider 41 of FIG. 11, can befixed to the cap region 67.

[0046] The solution shown in FIGS. 13-16 thus provides a micromechanicalstructure 57 protected by a cap, for example cap region 67, and easilyconnects the circuit 40 both to the micromechanical structure 57 and tothe outside.

[0047]FIG. 17 shows a variation of the structure of FIG. 16, in whichthe rotor 58 is not anchored to the substrate 53, but is supported bysprings (not shown) and biasing regions 60, similar to the biasingregions 31, 32 of FIG. 7. In addition, the cap region 67 is fixed anddoes not have the second trenches 72 b. The rotor 58 and stator 59 areconnected via connection regions 23 and pad regions 19 to metallicregions 13, 18 formed in the second wafer 10. The metallic regions 13are connected to the outside, as shown in the left-hand half of FIG. 17,via further connection regions 23 aligned with plug regions 62, 73formed in the first wafer 1, in a way similar to that described withreference to FIGS. 13-16, and via contacts 29. In addition, the metallicregions 18 enable connection of the circuit 40 to the stator 59 and, viaplug regions 62, 73 and contacts 29, to the outside, as shown in theright-hand half of FIG. 17. An insulating layer 80 covers the surface 26of the first wafer 1.

[0048]FIGS. 18 and 19 show a sixth embodiment, in which amicromechanical structure, for example an acceleration sensor 8, isprotected by a cap and electrically connected to the biasing and sensingcircuit via plug regions.

[0049] Initially, as illustrated in FIG. 18, the first wafer comprises asubstrate 53, which, in contrast to the previous embodiments, is notetched to form trenches. On the substrate 53, a sacrificial layer 54 isdeposited and defined, and is removed only at openings 55. Next, apolycrystalline silicon seed layer is deposited, and the epitaxial layer56 is grown, as described with reference to FIG. 14.

[0050] The epitaxial layer 56 is etched to form fifth trenches 65 a fordelimiting second plug portions 64. Here, the fifth trenches 65 a arefilled, either partially or completely, with insulating material 66,sixth trenches 65 b are formed for defining the accelerometric sensor 8,and the sacrificial layer 54 is partially removed through the sixthtrenches 65 b, so as to free the rotor 58 of the acceleration sensor 8.As for the embodiment shown in FIGS. 1-8, the rotor 58 is carried by thefixed part via springs (not illustrated).

[0051] Subsequently, the first wafer 1 is bonded to the second wafer 10using the connection regions 23 already formed on the surface 22 of thesecond wafer 10. Then the first wafer 1 is thinned by grinding until thedesired thickness for the substrate 53. Next, the substrate 53 isselectively removed so as to form a cap region 67 of larger dimensionsthan the rotor 58, but of smaller dimensions than the chip housing thecircuit 40, obtained after cutting the wafers 1, 10. In this way, thecap region 67 covers the rotor 58 from the back, protecting itmechanically, but leaves the plug regions 64 free.

[0052] Finally, the contacts 29 and the electric connection lines 30 areformed, which, in this embodiment, contact directly the silicon of theepitaxial layer 54. In particular, in the example illustrated in FIG.19, an electric connection line 30 connects a region (not shown),arranged inside the fixed part and is electrically connected to therotor 58, to the plug region 64 on the left, and thus to the circuit 40.A ball-and-wire connection on the right instead enables connection ofthe circuit 40 to the outside.

[0053] When the acceleration sensor 8 is to be kept at low pressure, forexample to reduce friction with air during movement, a sealing region 49may be provided which surrounds the area of the acceleration sensor 8,then the first wafer 1 may be bonded to the second wafer 10 in vacuumconditions, as already described with reference to FIG. 12.

[0054] The advantages of the process and structures described areevident from the above. In particular, they enable mechanical connectionof two bodies of semiconductor material, in particular ofmonocrystalline silicon, arranged on one another, and at the same timethe electrical connection of a structure or circuit formed in theunderlying body, which is covered by the overlying body, to the outsideor to a structure made in the overlying body; or else, they enableelectrical connection of the underlying body to regions arranged abovethe overlying body, without requiring complicated and costly processesto be carried out from the back, without damaging the structures andcircuits already made, and applying single manufacture steps that arecommonly used in the manufacture of wafers of semiconductor material forforming micro-electromechanical structures.

[0055] The described solutions moreover make it possible, whennecessary, to isolate preset areas of the underlying body and/or of theoverlying body from the outside environment, for example to enclosedelicate elements in a low-pressure environment, and/or to isolate andprevent contamination of these elements during manufacture, for examplecutting semiconductor material wafers, during subsequent manipulationsteps, and during use.

[0056] Finally, it is clear that numerous modifications and variationsmay be made to the connection structure, the composite structure, and tothe manufacture process described and illustrated herein, all fallingwithin the scope of the invention, as defined in the attached claims. Inparticular, the present connection structure may be used for a widerange of applications, both for the connection of electronic circuitsintegrated in two or more different substrates, and for the connectionof micro-electromechanical structures of various kinds tobiasing/control/sensing circuits associated to themicro-electromechanical structures. The present connection structure maybe used for connecting a high number of substrates, according to therequirements and to general considerations of a mechanical/electricalnature.

1. An electric connecting structure for connecting a first body ofsemiconductor material overlaid by a second body of semiconductormaterial, the connecting structure comprising: a plug region extendingthrough a portion of said second body and made of semiconductormaterial; an insulation region surrounding laterally said plug region;and a first electromechanical connection region of electricallyconductive material arranged between said first body and said secondbody and in electrical contact with said plug region and with conductiveregions of said first body.
 2. The electric connection structure ofclaim 1 , wherein said plug region extends throughout a thickness ofsaid second body and has a first face and a second face, said first facebeing in contact with said first electromechanical connection region;and further comprising a contact region of electrically conductingmaterial in contact with said second face of said plug region.
 3. Theelectric connection structure of claim 2 , further comprising anelectric connection line extending above said second body and having afirst end forming said contact region.
 4. The electric connectionstructure of claim 3 , wherein said electric connection line has asecond end in electrical contact with a conductive region of said secondbody.
 5. The electric connection structure of claim 3 , wherein saidelectric connection line has a second end in electrical contact with acontact region formed on a third body fixed to said second body.
 6. Theelectric connection structure of claim 2 , for electrically connectingsaid second body to a third body of semiconductor material arranged onsaid second body, wherein said contact region further comprises at leastone second electromechanical connection region made of a materialresulting from the chemical reaction of said semiconductor material witha metal, said second electromechanical connection regions being arrangedbetween said second body and said third body.
 7. The electric connectionstructure of claim 1 , for a second body comprising a substrate regionand an epitaxial region arranged on each other and partially insulatedfrom one another by insulating regions, wherein: said plug regionfurther comprises a first plug portion extending throughout thethickness of said substrate region, and a second plug portion formedinside said epitaxial region, said second plug portion being aligned andin direct electrical contact with said first plug portion; saidinsulation region further comprises a first insulation portion laterallysurrounding said first plug portion, and a second insulation portionlaterally surrounding said second plug portion; a contact region ofelectrically conducting material extends on a free face of saidsubstrate region in electrical contact with said first plug portion; andsaid second plug portion faces and is in direct electrical contact withsaid first electromechanical connection region.
 8. The electricconnection structure of claim 1 , for a second body comprising asubstrate region and an epitaxial region arranged on one another andreciprocally insulated by insulating regions, wherein said substrateregion has a smaller area than said epitaxial region, said plug regionextends throughout the thickness of said epitaxial region, and has afirst face and a second face, said first face being in contact with saidfirst electromechanical connection region, and said second face being indirect contact with at least one electric connection region ofelectrically conducting material.
 9. The electric connection structureaccording to claim 1 , wherein said insulation region comprises a trenchhaving a closed shape filled at least partially with insulatingmaterial.
 10. The electric connection structure according to claim 1 ,wherein said first electromechanical connection region is made of amaterial resulting from the chemical reaction of said semiconductormaterial with a metal.
 11. The electric connection structure accordingto claim 1 , wherein said first electromechanical connection region ismade of a metal resulting from the chemical reaction of silicon with ametal chosen from among a group comprising gold, palladium, titanium,and nickel.
 12. A composite structure comprising: a first body ofsemiconductor material; a second body of semiconductor material arrangedon said first body); and an electric connection structure, including: aplug region extending through a portion of said second body and made ofsemiconductor material, an insulation region laterally surrounding saidplug region, and a first electromechanical connection region ofelectrically conductive material arranged between said first body andsaid second body and in electrical contact with said plug region andwith conductive regions of said first body.
 13. The composite structureaccording to claim 12 , wherein said plug region extends throughout thethickness of said second body and has a first face and a second face,said first face being in contact with said first electromechanicalconnection region; further comprising a contact region of electricallyconducting material, in contact with said second face of said plugregion; and wherein said first body houses an electronic circuit); andsaid second body houses a micro-electromechanical device comprising afixed part and a mobile part separated from each other by at least onedelimitation trench extending through said second body.
 14. Thecomposite structure of claim 13 , further comprising an externalelectric connection wire bonded to said contact region.
 15. Thecomposite structure of claim 13 , wherein said electric connectionstructure further comprises an electric connection line extending abovesaid second body and having a first end forming said contact region, anda second end in electrical contact with said micro-electromechanicaldevice.
 16. The composite structure of claim 13 , further comprising athird body fixed to said second body, said electric connection structurefurther comprising an electric connection line having a first endforming said contact region and a second end in electrical contact witha contact region formed on said third body.
 17. The composite structureof claim 16 , wherein said third body is a slider, and said compositestructure forms an actuator unit for micrometric position regulation ofa hard-disk driver.
 18. The composite structure of claim 12 , whereinthe first body of semiconductor material further houses a firstelectronic circuit; further comprising a third body of semiconductormaterial and housing a second electronic circuit, said third body fixedto said second body; and the electric connection structure, wherein:said plug region includes a first face and a second face, said plugregion connecting together said first and second electronic circuits,said first electromechanical connection region arranged between saidfirst body and said second body is further in electrical contact withsaid first face of said plug region, and further comprising a contactregion of electrically conducting material in contact with said secondface of said plug region, the contact region having at least one secondelectromechanical connection region made of a material resulting fromthe chemical reaction of said semiconductor material with a metal, saidsecond electromechanical connection regions being arranged between saidsecond body and said third body.
 19. The composite structure of claim 18, further comprising a sealing region having a closed shape and arrangedbetween said first and said second bodies, outside one of said first andsecond electronic circuits.
 20. A composite structure comprising: afirst body of semiconductor material; a second body of semiconductormaterial arranged on said first body and comprising a an epitaxialregion housing a micro-electromechanical device having a fixed part anda mobile part separated from one another by a delimitation trenchextending through said epitaxial region and a substrate region forming acap region and arranged over the mobile part of said epitaxial region,said epitaxial region and said substrate region being arranged on eachother and partially insulated from one another by first and secondinsulating regions; and an electric connection structure, including: afirst plug portion formed of semiconductor material and extendingthroughout the thickness of said substrate region, a second plug portionformed of semiconductor material and formed inside said epitaxialregion, said second plug portion being aligned and in direct electricalcontact with said first plug portion and further facing and in directelectrical contact with a first electromechanical connection region,said first electromechanical connection region being formed ofelectrically conductive material arranged between said first body andsaid second body and in electrical contact with conductive regions ofsaid first body, said first insulation portion laterally surroundingsaid first plug portion, and said second insulation portion laterallysurrounding said second plug portion; and a contact region ofelectrically conducting material extending on a free face of saidsubstrate region in electrical contact with said first plug portion. 21.A composite structure comprising: a first body of semiconductormaterial; a second body of semiconductor material arranged on said firstbody and comprising an epitaxial region housing amicro-electromechanical device comprising a fixed part and a mobile partseparated from one another by at least one delimitation trench extendingthrough said epitaxial region and a substrate region forming a capregion which has larger dimensions than said mobile part and is fixed tosaid fixed part, said epitaxial region and said substrate regionoverlaid to each other and reciprocally insulated from one another byinsulating regions; and an electric connection structure, including: aplug region extending throughout the thickness of said epitaxial regionof said second body and made of semiconductor material, said plug regionhaving a first face and a second face, said first face being in contactwith a first electromechanical connection region, and said second facebeing in direct contact with at least one electric connection region ofelectrically conducting material, said first electromechanicalconnection region of electrically conductive material arranged betweensaid first body and said second body and in electrical contact with saidplug region and with conductive regions of said first body, and aninsulation region laterally surrounding said plug region.
 22. A processfor manufacturing a composite structure, comprising: forming a plugregion surrounded by an insulation region extending through a firstwafer of semiconductor material; forming an electromechanical-connectionregion of conductive material on a second wafer of semiconductormaterial, and aligned with said plug region; bringing said first waferand said second wafer close together, bringing said plug region intocontact with said electromechanical-connection; and fixing said firstwafer and said second wafer through said electromechanical connectionregion.
 23. The process of claim 22 , further comprising: initiallyforming said insulation region in said first wafer, said insulationregion partially extending inside said first wafer from a surface ofsaid first wafer and laterally delimiting said one plug region; turningsaid first wafer upside down to bring said surface of said first waferin a facing position with said second wafer; and thinning said firstwafer until said insulation region.
 24. The process of claim 23 ,wherein said forming said insulation region further comprises: formingisolation trenches in said first wafer; and at least partially fillingsaid isolation trenches with insulating material.
 25. The process ofclaim 24 , further comprising forming trenches delimiting amicro-electromechanical structure in said first wafer, and forming anelectronic circuit in said second wafer before forming saidelectromechanical-connection region.
 26. The process of claim 22 ,further comprising: forming a first insulation portion of saidinsulation region in a substrate of semiconductor material, said firstinsulation portion partially extending inside said substrate from asurface of said substrate, and laterally delimiting a first plug portionof said plug region; growing an epitaxial layer from said surface ofsaid substrate; forming at least one second insulation portion of saidinsulation region in said epitaxial layer, said second insulationportion extending throughout the thickness of said epitaxial layer anddelimiting a second plug portion of said plug region which issubstantially aligned and in electrical contact with said first plugportion; fixing said second plug portion to said second wafer; thinningsaid substrate until said first insulation portion; and forming contactregions on a free face of said substrate.
 27. The process of claim 22 ,further comprising: on a substrate, growing an epitaxial layer; formingsaid insulation region in said epitaxial layer, said insulation regionextending throughout the thickness of said epitaxial layer anddelimiting said plug region; forming a device to be protected in saidepitaxial layer; fixing said epitaxial layer of said first wafer to saidsecond wafer through said plug region; selectively removing saidsubstrate to form a cap region covering said device to be protected, andfreeing said plug region; and forming contact regions above said plugregion.
 28. The process according to claim 22 , wherein said step offixing said first wafer to said second wafer is carried out in vacuumconditions and further comprises forming a sealing region between saidfirst wafer and said second wafer.
 29. The process according to claim 22, wherein said conductive material of said electromechanical connectionregion is a metal, and said fixing further comprises causing said metalof said electromechanical-connection structure to react with saidsemiconductor material of said plug region.